For functional groups not represented by multi-stanza population dynamics accounting, Ecospace represents biomass (B<\/em>) dynamics over a set of spatial cells (k<\/em>) with the spatially discretized rate formulation<\/p>\r\n[latex]dB_{ik}\/dt=g_iQ_{ik}-Z_{ik}B_{ik}-(\\sum\\limits_km_{ikk'})B_{ik}+\\sum\\limits_{k'}m_{ik'k}B_{ik'} \\tag{1}[\/latex]\r\n where B<\/em>ik<\/em> is the biomass of functional group i<\/em> in spatial cell k;<\/em> g<\/em>i<\/em><\/sub> is conversion efficiency of food intake by group i <\/em>into net production; Q<\/em>ik<\/em><\/sub> is total food consumption rate by group i<\/em> in spatial cell k;<\/em> Z<\/em>ik<\/em><\/sub> is total mortality rate of group i<\/em> biomass due to predation, fishing, etc.; m<\/em>ikk<\/em>\u0384<\/sub> is instantaneous movement rate of group i<\/em> biomass from cell k<\/em> to cell k<\/em>\u0384; and m<\/em>ik<\/em>\u0384k<\/em><\/sub> is movement rate of group i<\/em> biomass from cell k<\/em>\u0384 to cell k<\/em>.<\/p>\r\n All of the terms on the right hand side of Eq. 1, except g<\/em>i<\/em><\/sub>, are treated as dynamically variable over time so as to reflect changes in food availability (Q<\/em>ik<\/em><\/sub>), fishing effort and predation risk (Z<\/em>ik<\/em><\/sub>), and seasonal changes in movement patterns (m<\/em>ikk<\/em>\u0384<\/sub>). Food consumption rates Q<\/em>ik<\/em><\/sub> are calculated as sums over prey types j<\/em> (i.e., Q<\/em>ik<\/em><\/sub> = \u03a3jQ<\/em>jik<\/em><\/sub>). Likewise, total mortality rates are calculated as sums over predator types and fishing fleets f:<\/em> Z<\/em>ik<\/em><\/sub> = M<\/em>oi<\/em><\/sub> + \u03a3f<\/sub> F<\/em>ifk<\/em><\/sub> + \u03a3j<\/sub>Q<\/em>ijk<\/em><\/sub>\/B<\/em>ik <\/em><\/sub>, where M<\/em>oi<\/em><\/sub> is unexplained mortality rate, the fishing rate components F<\/em>ifk<\/em><\/sub> by fleets f<\/em> are predicted from spatial distributions of fishing effort for each \u201cfleet\u201d f<\/em> over the grid cells k<\/em>, and the Q<\/em>ijk<\/em><\/sub>\/B<\/em>ik<\/em><\/sub> ratios represent predation rate components of M<\/em> (i.e., M<\/em>ijk<\/em><\/sub> = Q<\/em>ijk<\/em><\/sub>\/B<\/em>ik<\/em><\/sub>) calculated from predator j<\/em> consumption rates Q<\/em>ijk<\/em><\/sub>.<\/p>\r\n The Ecospace grid cells are arranged as a rectangular grid with rows r<\/em> and columns c<\/em>, so that each cell k<\/em> exchanges biomass directly only with those cells k<\/em>\u0384 that are in adjacent rows and columns. If cell k<\/em> represents row r<\/em>, column c<\/em>, then k<\/em>\u0384 is restricted to cells (r<\/em> \u2013 1,c<\/em>), (r<\/em> + 1,c<\/em>), (c<\/em> \u2013 1,r<\/em>), and (c<\/em> + 1,r<\/em>). Exchanges at the map perimeter are set to zero, except for groups that are assumed to be advected across the map, in which case biomasses at the map boundary are set to constant (Ecopath base estimate) values.<\/p>\r\n\r\n The basic accounting relationships for multi-stanza groups are<\/p>\r\n[latex]N_{a+1,t+1}=N_{a,t} \\exp(-Z_{s,t}\/12) \\tag{2}[\/latex]<\/a>\r\n\r\n[latex]W_{a+1,t+1}=\\alpha_a q_{a,t}+ \\rho W_{a,t} \\tag{3}[\/latex]<\/a>\r\n\r\n[latex]B_{s,t}=\\sum\\limits_{a=a1(s)}^{a2(s)} N_{a,t}W_{a,t} \\tag{4}[\/latex]<\/a>\r\n Here, N<\/em>a,t<\/em><\/sub> is number of age a<\/em> (in months) animals in calendar month t<\/em>, W<\/em>a,t<\/em><\/sub> is mean body weight of age a<\/em> animals in month t<\/em>, and B<\/em>s,t<\/em><\/sub> is the biomass of stanza s<\/em>, defined as the mass (numbers \u00d7 weight) of animals aged a<\/em>1(s<\/em>) through a<\/em>2(s<\/em>) months. Z<\/em>s,t<\/em><\/sub> is the total mortality rate of stanza s <\/em>animals, defined the same way on the basis of fishing and consumption as for other model biomass groups i<\/em> as Z<\/em>s,t<\/em><\/sub> = M<\/em>os<\/em><\/sub> + \u03a3f<\/sub>F<\/em>sf<\/em><\/sub> + \u03a3j<\/sub>Q<\/em>sj<\/em><\/sub>\/B<\/em>s<\/em><\/sub>. All animals in stanza s are treated as having the same predation risk and vulnerability to fishing. The aggregated bioenergetics parameters a<\/em>a<\/em><\/sub> and r<\/em> are calculated to make body growth follow a von Bertalanffy growth curve (with length-weight power 3.0) with user-defined metabolic parameter K<\/em>. Exact von Bertalanffy growth occurs when predicted per-capita food intake q<\/em>a,t<\/em><\/sub> is equal to a base food intake rate that is calculated from the consumption per biomass parameter (Q<\/em>s<\/em><\/sub>\/B<\/em>s<\/em><\/sub>) provided by the user for each stanza. The metabolic parameter r<\/em>, which equals exp(\u20133K<\/em>\/12), is based on the assumption that metabolism is proportional to body weight[footnote]Essington, T. E., J. F. Kitchell, and C. J. Walters. 2001. The von Bertalanffy growth function, bioenergetics, and the consumption rates of fish. Can. J. Fish. Aquat. Sci. 28: 2129\u20132138. https:\/\/doi.org\/10.1139\/f01-151<\/a>[\/footnote].<\/p>\r\n Actual or realized food intake q<\/em>s,t<\/em><\/sub> at each time step is calculated from the total predicted food-intake rate for the stanza (Q<\/em>s,t<\/em><\/sub>) as q<\/em>s,t<\/em><\/sub> = Q<\/em>s<\/sub>,tw<\/sub><\/em>a,t<\/sub><\/em>2\/3<\/sup>\/P<\/em>s,t<\/sub>,<\/em> where P<\/em>s,t<\/em><\/sub> is the relative total area searched for food by stanza s<\/em> animals and is computed as P<\/em>s,t<\/em><\/sub> = \u03a3a<\/sub>N<\/em>a,tw<\/em>a,t<\/em><\/sub>2\/3<\/sup>. For foraging-arena food-intake and predation-rate calculations involving stanzas<\/em>, P<\/em>s,t<\/em><\/sub> is used instead of B<\/em>s<\/em><\/sub> as the predictor of total area or volume searched for food per unit time. The assumption that area searched and food intake vary as the \u2154 power of weight (i.e., as the square of body length) is a basic assumption that also underlies the derivation of the von Bertalanffy growth function. For notational simplicity, Eqs. 2-4 above are presented without a species index.<\/p>\r\n\r\n<\/div>\r\n [latex]\\bar P_s=\\sum\\limits_aN_{a,0}W_{a,0}\/\\sum\\limits_aN_{a,0}\\tag{5}[\/latex]<\/p>\r\nDynamics of the numbers in each stanza Ns<\/sub><\/em> were computed for each cell by the differential equation\r\n\r\n[latex]dN_{sk}\/dt=R_{sk}-Z_{sk}N_{sk}-(\\sum\\limits_{k'}m_{ik'k}N_{sk})\\tag{6}[\/latex]\r\n\r\nwhere Rsk<\/sub><\/em> is an approximate difference between recruitment (incoming) rates and exit (to next stanza) rates for stanza s<\/em> in spatial cell k<\/em>. If the age structure within the stanza is assumed to remain near equilibrium, the Rsk<\/sub><\/em> term in Eq. 6 can be approximated as\r\n\r\n[latex]R_{1k} = E_{tk} (1-exp(Z_{sk}(a_2(1))\/12)) \\; \\text{for} \\; s = 1 \\tag{7a}[\/latex]\r\n\r\n[latex]R_{sk} = N_{s-1,k} Z_{s-1,k} \/ (\\exp(Z_{s-1,k}(a_2(s-1)-a_1(s-1))\/12)-1) \\; \\text{for} \\; s>1 \\tag{7b}[\/latex]\r\n\r\nEq. 7a represents egg production rate minus survival rate to the age at exit from stanza s<\/em> = 1. Egg production is assumed to be approximately proportional to biomass Bsk<\/sub><\/em> of the oldest (adult) stanza s<\/em> in cell k<\/em>. Eq. 7b is derived from the equilibrium of the delay-differential equation for Ns<\/sub><\/em> that results from assuming spatial gain and loss rates to be approximately balanced, so that the dominant effects on NOriginal representation of multi-stanzas in Ecospace<\/h2>\r\nWhen the multi-stanza option was originally developed for Ecosim, it was not incorporated directly into Ecospace. Instead, each stanza was treated as its own higher-order functional group for Ecospace biomass-dynamics calculations without accounting for age structure within the stanza. Rather, the age-structure of each stanza was assumed to be in equilibrium. Body weight was computed grid-wide (not cell-specifically) for each stanza. Feeding rates were assumed proportional to a relative search-area index Ps<\/sub><\/em> calculated from a prediction of the numerical abundance of the stanza Ns<\/sub><\/em> as Ps<\/sub> = Ns<\/sub>\u0305Ps<\/sub><\/em>, where \u0305Ps<\/sub><\/em> is the initial (t = 0) per-capita mean of the relative area-searched index P<\/em>s,t<\/sub>, i.e.,\r\n